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Biochemistry 2006, 45, 3554-3562
Affinity Labeling of the Rabbit 12/15-Lipoxygenase Using Azido Derivatives of Arachidonic Acid† Stepan Romanov,‡,§ Rainer Wiesner,‡ Galina Myagkova,§ Hartmut Kuhn,*,‡ and Igor Ivanov‡,§ Institute of Biochemistry, UniVersity Medicine BerlinsCharite´ , Monbijoustrasse 2, 10117 Berlin, Germany, and LomonosoV State Academy of Fine Chemical Technology, 119571 Moscow, Russian Federation ReceiVed October 21, 2005; ReVised Manuscript ReceiVed January 20, 2006
ABSTRACT: Lipoxygenases are lipid-peroxidizing enzymes, which have been implicated in the pathogenesis of important diseases. They consist of a single polypeptide chain, which is folded into a two-domain structure. The large catalytic domain contains the putative substrate-binding pocket and the catalytic nonheme iron. To identify structural elements of the rabbit 12/15-lipoxygenase that are involved in enzyme/ substrate and/or enzyme/product interaction, we synthesized a set of radioactively labeled lipoxygenase substrates carrying a photoreactive azido group (17-azido-ETE, 18-azido-ETE, 19-azido-ETE) and used these compounds as affinity probes. After photoaffinity labeling, the enzyme was digested proteolytically and modified tryptic cleavage peptides were identified by a combination of radio-HPLC and mass spectral analysis. Following this strategy, we observed covalent linkage of a cleavage peptide that contained Ile593, which has previously been identified as the sequence determinant for the positional specificity. These data are consistent with the previous suggestion that this peptide lines the substrate-binding pocket. Surprisingly, we also observed strong labeling of cleavage peptides originating from the N-terminal β-barrel domain, and our mass spectral data suggested covalent linkage of oxidized affinity probes. Taken together, these results confirm the previous conclusion that Ile593 and surrounding amino acids are constituents of the active site, but they also implicate the N-terminal β-barrel in enzyme/substrate and/or enzyme/product interaction.
Lipoxygenases constitute a heterogeneous family of fatty acid dioxygenases that are widely distributed in plants and animals (1, 2). Completion of the human genome project revealed that there are six functional LOX1 genes, which encode for six different human isoenzymes (3). The biological activity of most mammalian LOX-isoforms is not completely understood, but five LOXs are involved in the biosynthesis of inflammatory leukotrienes (1). Other LOXisozymes have been implicated in cell differentiation (4), cancer metastasis (5), and atherogenesis (6). More recently, involvement of 15-LOX1 in bone development has been suggested (7). The structural biology of the LOX family is not welldeveloped. For now, the crystal structures of two plant LOX† Financial support was provided by the Humboldt Foundation (RUS111557), DAAD (A/03/01297), and the European Commission (FP6, LSHM-CT-2004-0050333). * To whom correspondence should be addressed: Dr. Hartmut Kuhn, Institute of Biochemistry, University Medicine BerlinsCharite, Humboldt University, Monbijoustr. 2, 10117 Berlin, F. R. Germany. Tel, +49-30-450528040;fax,+49-30-450528905;e-mail,
[email protected]. ‡ University Medicine BerlinzsCharite´. § Lomonosov State Academy of Fine Chemical Technology. 1 Abbreviations: RP-HPLC, reverse-phase high-performance liquid chromatography; SP-HPLC, straight-phase high-performance liquid chromatography; LOXs, lipoxygenases; GC/MS, gas chromatography/ mass spectrometry; AA, (5Z,8Z,11Z,14Z)-eicosa-5,8,11,14-tetraenoic (arachidonic) acid; [3H8]-17-azido-ETE, [5,6,8,9,11,12,14,15-3H8](5Z,8Z,11Z,14Z)-17-azidoeicosa-5,8,11,14-tetraenoic acid; [3H8]-18azido-ETE, [5,6,8,9,11,12,14,15-3H8]-(5Z,8Z,11Z,14Z)-18-azidoeicosa5,8,11,14-tetraenoic acid; [3H8]-19-azido-ETE, [5,6,8,9,11,12,14,153 H8]-(5Z,8Z,11Z,14Z)-19-azidoeicosa-5,8,11,14-tetraenoic acid.
isoforms [soybean LOX-1 (8, 9) and LOX-3 (10)] and one mammalian enzyme/inhibitor complex (11) have been reported, and there are additional data sets for various plant LOX-ligand complexes (12, 13). Moreover, a 3D-model for the structure of the human 5-LOX has been worked out (14). All LOX-isoforms constitute single polypeptide molecules that are folded into a two-domain structure (8-11). The large C-terminal catalytic domain of the rabbit 15-LOX-1 comprises about 550 amino acids and is largely helical (11). It contains the catalytic non-heme iron, which is buried deeply inside the putative substrate-binding pocket. Its small Nterminal domain involves 110 amino acids and consists of two four-stranded antiparallel β-sheets. It shares a 1.600 Å2 interface with the catalytic domain (11), and the two domains are covalently interconnected by an unstructured stretch (random coil) of amino acids (residues 111-124). The soybean LOX-1, which is composed of 839 amino acids, does also fold into a two-domain structure (8, 9). The two subunits share a 2.600 Å2 contact plane, and the interdomain interface constitutes a solvent-filled crevice (9). Detailed evaluation of the corresponding X-ray coordinates (comparison of the B-value pattern) suggested that the overall structures of the two domains are rather stable but that the N-terminal β-barrel domain may move as stable unit relative to the catalytic subunit (9). Recent investigations into the solution structure of the rabbit 15-LOXs (15) are supportive for this hypothesis, but similar experiments on the soybean LOX did not reveal any indications for significant interdomain movement (16).
10.1021/bi052152i CCC: $33.50 © 2006 American Chemical Society Published on Web 02/28/2006
Photoaffinity Labeling of 12/15-LOX Despite this structural information, the binding fatty acid derivatives at the active site of mammalian LOXs have not been investigated in detail. There is no crystal structure of a mammalian LOX-substrate complex, and affinity-labeling studies have not been carried out. In addition, the functional relevance of the N-terminal β-barrel domain is far from understood. Limited proteolysis studies on the soybean LOX-1 led to the formation of a truncated LOX-form that lacked the N-terminal β-barrel (17). This mini-LOX was catalytically active and exhibited an impaired affinity for linoleic acid (KM of 11.2 µM for native and 24.2 µM for mini-LOX). On the other hand, Vmax of linoleic acid oxygenation was augmented (363 s-1 for mini-LOX vs 55 s-1 for the native enzyme). These data suggested that the N-terminal β-barrel domain may not be essential for the catalytic cycle but might be involved in substrate binding and/or product dissociation. Gene technical truncation of the N-terminal β-barrel domain of the rabbit 15-LOX (18) led to the formation of a mini-LOX, which exhibited a similar substrate affinity as the native enzyme (7.0 µM for miniLOX vs 11.4 µM for the native enzyme) but a lower catalytic activity (Vmax of 9.9 s-1 for the native enzyme vs 1.6 s-1 for the mini-LOX). To explore which structural elements of the rabbit 12/15LOX directly interact with fatty acid substrates and/or hydroperoxy fatty acid activators, we initiated experiments using a specific affinity probe. For this purpose, we synthesized (19, 20) a set of radioactively labeled arachidonic acid derivatives, which carry a photoreactive azido group at different carbon atoms of the fatty acid backbone (17-azidoETE, 18-azido-ETE, 19-azido-ETE) and incubated these compounds with the purified rabbit 15-LOX. After tryptic digestion, we identified labeled cleavage peptides and assigned them to the 3D-structure of the enzyme. Among labeled cleavage fragments, we identified a 3.5 kDa peptide (amino acids 571-599) that contained the amino acid I593, which has previously identified as sequence determinant for the positional specificity of the rabbit enzyme (21). In the 3D-structure, I593 acid is localized in immediate proximity to L589 and Q590, which constitute sequence determinants for the positional specificity of the human 15-LOX2 (22), and thus, this region of the primary structure appears to line the substrate-binding cleft of the enzyme. Surprisingly, we also observed strong labeling of β-barrel domain peptides. These data suggest that the N-terminal β-barrel domain, which does not contribute to the active site according to the X-ray coordinates, appears to interact with substrate fatty acids and/or their oxygenation products. MATERIALS AND METHODS Chemicals. The chemicals used were from the following sources: sodium borohydride from Serva (Heidelberg, Germany); nitrosomethyl urea, bis[trimethylsilyl]trifluoroacetamide (BSTFA), and trypsin from Sigma (Deisenhofen, Germany); 10% Pd/CaCO3 (catalyst for hydrogenation) from Aldrich (Taufkirchen, Germany). All solvents were of HPLC grade and purchased from Baker (Deventer, The Netherlands). The azido fatty acids used in this study were synthesized as reported before (19, 20). Preparation of the NatiVe Rabbit 15-LOX. The native reticulocyte-type 15-LOX was prepared from the stroma-
Biochemistry, Vol. 45, No. 11, 2006 3555 free hemolysis supernatant of a reticulocyte-rich blood cell suspension by sequential ammonium sulfate precipitation, hydrophobic interaction chromatography, and anion exchange chromatography on a preparative Mono-Q column (Pharmacia, Uppsala, Sweden). The final enzyme preparation was electrophoretically pure (6 Å) to the reactive azido group. The strong labeling of cleavage peptides of the N-terminal β-barrel domain was rather surprising since this structural element has not been implicated in enzyme/substrate and/or enzyme/product interactions. In general, the function of the N-terminal β-barrel domain is still a matter of discussion. The high degree of conservation of the two-domain structure in most LOXs suggests the catalytic importance of this structural element, but for now, its functionality is far from clear. Because of its structural similarity to the β-barrel
domain of human lipases (32), the N-terminal domains of mammalian LOXs have been implicated in membrane binding. Indeed, site-directed mutagenesis of surface-exposed tryptophanes in the N-terminal domain impaired membrane binding of the human 5-LOX (33). For the rabbit 12/15LOX gene, technical truncation of the β-barrel domain also induced impairment of membrane binding, but site-directed mutagenesis studies suggested that surface-exposed amino acids in both domains are involved in membrane binding (18). For the soybean LOX1, proteolytic cleavage of the N-terminal β-barrel domain augmented its membrane binding capacity (17), which contrasts the results obtained with the two mammalian LOXs (5-LOX and 12/15-LOX). To precisely define the role of the N-terminal β-barrel domain in membrane binding, truncation and mutagenesis studies on other LOX-isoforms should be carried out and such experiments are underway in our laboratory. In addition to a possible role in membrane binding, a regulatory activity of the β-barrel domain for the catalytic reaction has been suggested (17, 18). Gene technical truncation of the rabbit 12/15-LOX impaired the catalytic efficiency of the enzyme (18), whereas limited proteolysis of the soybean LOX1 augmented oxygenase activity (17). Moreover, suicidal inactivation of LOXs appears to be regulated by the β-barrel domain. It has been reported previously and was confirmed in this study that the N-terminal truncation mutant of the rabbit 12/15-LOX undergoes more rapid suicidal inactivation during arachidonic acid oxygenation when compared with the wild-type enzyme. The N-terminal truncation mutant completely lost its activity within the first 20 s of arachidonic acid oxygenation (Figure 5A), and similar results were obtained when the enzyme was incubated in the presence of 2 µM 15-HpETE (Figure 5B). In contrast, the complete recombinant enzyme was much more stable (Figure 5). These data, together with our finding that β-barrel domain cleavage peptides were covalently linked to oxygenated derivatives of 19-azido-ETE, strongly suggest that this domain may be involved in peroxide binding and, thus, appears to be of dual regulatory importance for catalytic efficiency. It may impact both peroxide-dependent enzyme activation and suicidal inactivation. Another catalytic subprocess, which might be impacted by the β-barrel domain, is substrate binding. Kinetic studies on the N-terminal-truncated mini-LOXs from soybeans indicated an impaired affinity for substrate fatty acids (KM of 11.2 µM for native and 24.2 µM for mini-LOX),
3560 Biochemistry, Vol. 45, No. 11, 2006
FIGURE 4: Affinity-modified tryptic cleavage peptides. The rabbit 12/15-LOX was affinity-labeled with nonradioactive 19-azido-ETE as described in the legend of Table 1, and the most prominent modified cleavage peptides are shown. The X-ray coordinates (11) of the rabbit 12/15-LOX were used to construct the structural model of the enzyme/substrate complex (PDB entry 1LOX). The residues, which were not defined in the crystal structure (601-602, 210211, 177-187), were inserted in silico using the molecular visualization program VMD (23), and energy was minimized using the molecular simulation program NAMD (24). Modeling of the enzyme substrate complex has been reported before (21). (A) Affinity labeling of the active site peptide (peptide VII in Table 1) containing the sequence determinant for the positional specificity I593. Potential candidate amino acids for covalent linkage are indicated (see text). (B) The modified tryptic cleavage peptide I, IV, and V, which together comprise more the 90% of the N-terminal β-barrel domain, are shown in different colors.
suggesting a role of the N-terminal domain in substrate acquisition (17). Our finding of strong affinity labeling of cleavage peptides of the N-terminal domain is consistent with this hypothesis, and the fact that we only detected linkageoxidized 19-azido-ETE does not argue against this hypothesis. Oxygenated polyenoic fatty acids are true LOX substrates, which are converted to double (28, 34) or triple oxygenation products (29), to epoxy leukotrienes (30, 35), and hepoxilins (36). These reactions require proper substrate alignment at the active site, and the N-terminal β-barrel domain may help to achieve this goal. Moreover, our failure to detect linkage of the nonoxidized affinity probe may be related to technical problems. Under our experimental
Romanov et al.
FIGURE 5: Impact of β-barrel domain on the reaction kinetics of the recombinant rabbit 12/15-LOX. (A) Progress curves of arachidonic acid oxygenation. The wild-type recombinant 12/15-LOX and its β-barrel truncation mutant were expressed as His-tag fusion proteins and purified as described in Materials and Methods. Aliquots (1 µg of the wild-type enzyme and 8 µg of the truncation mutant) were used to assay the arachidonic acid oxygenase activity (100 µM) with a Shimadzu UV2100 spectrophotometer (reaction volume 1 mL). (B) Time course of 12/15-LOX inactivation by 15SHpETE: the recombinant 15-LOX (30 µg/mL) and the β-barrel truncation mutant (50 µg/mL) were incubated with 15S-HpETE (2 µM) in 0.1 M phosphate buffer, pH 7.4. At the times indicated, aliquots were taken off and the residual linoleic acid oxygenase activity was assayed. Each data point represents the mean of triplicate measurements.
conditions, 19-azido-ETE is rapidly oxygenated during the incubation period, and after about 3 s, almost the entire amount of affinity probe was oxidized. Although we attempted to keep the preincubation period (before irradiation) as short as possible, it could not be completely eliminated. Another potential problem, which should be taken into account when interpreting our labeling data, is the possibility that the oxygenated affinity probe exhibits an altered photoreactivity. Although such functional interaction of the two groups is rather unlikely because of their large physical distance (azido group at C19 and peroxy group at C15), it cannot be completely excluded. To avoid these problems, labeling studies should be carried out under anaerobic conditions. Unfortunately, complete anaerobiosis is difficult to achieve in our experimental setup since repeated evacuation of the sample and flushing with argon inactivates the enzyme. The specificity of the labeling process has not been studied in detail, and the surface exposure of the β-barrel domain may contribute to its heavy labeling. However, there are many unlabeled surface-exposed cleavage peptides of the
Photoaffinity Labeling of 12/15-LOX catalytic domain, suggesting a certain degree of specificity in β-domain labeling. Despite these methodological difficulties, the strong labeling of the N-terminal β-barrel domain suggested a role of this structural element in enzyme/substrate and/or enzyme/ product interactions. Since both processes are important for the efficiency of the catalytic cycle, the β-barrel domain of LOX appears to be of regulatory importance. Moreover, affinity labeling of an active site peptide that contains a sequence determinant for the positional specificity confirmed the previous hypothesis that the U-shaped cavity identified in the crystal structure constitutes the substrate-binding pocket. ACKNOWLEDGMENT The technical assistance of Ms. P. Kunert (MALDI-TOF analysis) is acknowledged. SUPPORTING INFORMATION AVAILABLE Peptide sequence of the rabbit reticulocyte 15-LOX and tables of mass ions detected in the HPLC fractions prepared from the native and affinity-labelled 15-LOX. This material is available free of charge via the Internet at http:// pubs.acs.org. REFERENCES 1. Brash, A. R. (1999) Lipoxygenases: occurrence, functions, catalysis, and acquisition of substrate, J. Biol. Chem. 274, 2367923682. 2. Grechkin, A. (1998) Recent developments in biochemistry of the plant lipoxygenase pathway, Prog. Lipid Res. 37, 317-352. 3. Funk, C. D., Chen, X. S., Johnson, E. N., and Zhao, L. (2002) Lipoxygenase genes and their targeted disruption, Prostaglandins Other Lipid Mediators 68-69, 303-312. 4. van Leyen, K., Duvoisin, R. M., Engelhardt, H., and Wiedmann, M. (1998) A function for lipoxygenase in programmed organelle degradation, Nature 395, 392-395. 5. Kim, E., Rundhaug, J. E., Benavides, F., Yang, P., Newman, R. A., and Fischer, S. M. (2005) An antitumorigenic role for murine 8S-lipoxygenase in skin carcinogenesis, Oncogene 224, 11741187. 6. Huo, Y., Zhao, L., Hyman, M. C., Shashkin, P., Harry, B. L., Burcin, T., Forlow, B., Stark, M. A., Smith, D. F., Clarke, S.; Srinivasan, S., Hedrick, C.C., Pratico`, D., Witztum, J. L., Nadler, J. L., Funk, C. D., and Ley, K. (2004) Critical role of macrophage 12/15-lipoxygenase for atherosclerosis in apolipoprotein E-deficient mice, Circulation 110, 2024-2031. 7. Klein, R. F., Allard, J., Avnur, Z., Nikolcheva, T., Rotstein, D., Carlos, A. S., Shea, M., Waters, R. V., Belknap, J. K., Peltz, G., and Orwoll, E. S. (2004) Regulation of bone mass in mice by the lipoxygenase gene Alox15, Science 303, 229-232. 8. Boyington, J. C., Gaffney, B. J., and Amzel, L. M. (1993) The three-dimensional structure of an arachidonic acid 15-lipoxygenase, Science 260, 1482-1486. 9. Minor, W., Steczko, J., Stec, B., Otwinowski, Z., Bolin, J. T., Walter, R., and Axelrod, B. (1996) Crystal structure of soybean lipoxygenase L-1 at 1.4 Å resolution, Biochemistry 35, 1068710701. 10. Skrzypczak-Jankun, E., Amzel, L. M., Kroa, B. A., and Funk, M. O., Jr. (1997) Structure of soybean lipoxygenase L3 and a comparison with its L1 isoenzyme, Proteins 29, 15-31. 11. Gillmor, S. A., Villasenor, A., Fletterick, R., Sigal, E., and Browner, M. F. (1997) The structure of mammalian 15-lipoxygenase reveals similarity to the lipases and the determinants of substrate specificity, Nat. Struct. Biol. 4, 1003-1009. 12. Skrzypeczak-Jankun, E., Bross, R. A., Carroll, R. T., Dunham, W. R., and Funk, M. O. (2001) Three-dimensional structure of a purple lipoxygenase, J. Am. Chem. Soc. 123, 10814-10820. 13. Borbulevych, O. Y., Jankun, J., Selman, S. H., and SkrzypeczakJankun, E. (2004) Lipoxygenase interactions with natural fla-
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